三相四桥臂逆变器的研究

为实现三相四线的交流输出,变流器电路采取四桥臂新型拓朴结构。其控制采取了三维电压空间矢量调制,并在DSP数字平台上编程实现,实验验证该系统具有良好的输出性能。     

高速公路跨线钢箱梁施工质量控制措施

钢箱梁具有自重轻、承载能力强、可在施工现场快速拼装的特点，因此，在高速公路跨线工程中得到了广泛的推广应用。     

数控回转头冲床自动编程系统

介绍了《数控回转头冲床自动编程系统》的功能和设计特点。它利用中Ｗｉｎｄｏｗｓ９５作为系统工作平台，直接利用产品设计时零件在计算机内的图形信息，采用人机交互方式进行数控编程，此系统适用于数控回转头冲床的自动编程，它是板金计算机辅助设计与制造（ＣＡＤ／ＣＡＭ）开发的关键。     

DEADBEAT COVARIANCE CONTROLLER DESIGN FOR SAMPLED-DATA SYSTEMS

ＭＰＬＥＤ－ＤＡＴＡ ＳＹＳＴＥＭＳTX＠霍沛军＠王子栋ＩｎｔｒｏｄｕｃｔｉｏｎＳａｍｐｌｅｄ－ｄａｔａｆｅｅｄｂａｃｋｃｏｎｔｒｏｌｈａｓｒｅｃｅｉｖｅｄｍｕｃｈａｔｅｎｔｉｏｎｉｎｔｈｅａｒｅａｏｆｃｏｎｔｒｏｌｓｙｓｔｅｍｄｅ－ｓｉｇｎｂｅｃａｕｓｅｏ...     

桩板结构路基的动力响应分析

桩板结构路基-无砟轨道结构是一种相对较新的结构。因此,结合变形控制条件对桩板结构的匹配和动力特性进行数值模拟分析是很有意义的。本文通过动力响应包括动变形、动应力和基面加速度等分析,讨论地基处理的范围和深度、桩端持力层的刚度等问题。研究表明,增大桩径和增大桩端持力土层的承载力或刚度均是降低变形的有效措施。根据断面竖向变形的影响范围,通过对承台两侧宽5 m、深10 m范围内的地基进行处理,对于减少变形是有效的。此外,本文提出的桩板结构-无砟轨道路基横断面尺寸可供设计参考。     

桥梁结构砼外观质量控制技术

文章针对影响桥梁结构混凝土外观质量的常见问题,分析其产生的原因,介绍了桥梁施工中混凝土外观质量的控制方法.     

论建筑施工企业经营及其项目管理的重要性

随着市场经济的发展,建筑施工企业面临着激烈的市场竞争,企业能否在市场竞争中立于不败之地,关键在于企业能否为社会提供质量高、工期短、造价低的建筑产品。由此可见项目的成本管理成了项目施工管理的核心内容。     

Fault-tolerant control of heavy-haul trains

The fault-tolerant control (FTC) of heavy-haul trains is discussed on the basis of the speed regulation proposed in previous works. The fault modes of trains are assumed and the corresponding fault detection and isolation (FDI) are studied. The FDI of sensor faults is based on a geometric approach for residual generators. The FDI of a braking system is based on the observation of the steady-state speed. From the difference of the steady-state speeds between the fault system and the faultless system, one can get fault information. Simulation tests were conducted on the suitability of the FDIs and the redesigned speed regulators. It is shown that the proposed FTC does not explicitly worsen the performance of the speed regulator in the case of a faultless system, while it obviously improves the performance of the speed regulator in the case of a faulty system.     

A novel fuzzy logic correctional algorithm for traction control systems on uneven low-friction road conditions

The traction control system (TCS) might prevent excessive skid of the driving wheels so as to enhance the driving performance and direction stability of the vehicle. But if driven on an uneven low-friction road, the vehicle body often vibrates severely due to the drastic fluctuations of driving wheels, and then the vehicle comfort might be reduced greatly. The vibrations could be hardly removed with traditional drive-slip control logic of the TCS. In this paper, a novel fuzzy logic controller has been brought forward, in which the vibration signals of the driving wheels are adopted as new controlled variables, and then the engine torque and the active brake pressure might be coordinately re-adjusted besides the basic logic of a traditional TCS. In the proposed controller, an adjustable engine torque and pressure compensation loop are adopted to constrain the drastic vehicle vibration. Thus, the wheel driving slips and the vibration degrees might be adjusted synchronously and effectively. The simulation results and the real vehicle tests validated that the proposed algorithm is effective and adaptable for a complicated uneven low-friction road.     

Development of advanced driver assistance systems with vehicle hardware-in-the-loop simulations

This paper presents a new method for the design and validation of advanced driver assistance systems (ADASs). With vehicle hardware-in-the-loop (VEHIL) simulations, the development process, and more specifically the validation phase, of intelligent vehicles is carried out safer, cheaper, and is more manageable. In the VEHIL laboratory, a full-scale ADAS-equipped vehicle is set up in a hardware-in-the-loop simulation environment, where a chassis dynamometer is used to emulate the road interaction and robot vehicles to represent other traffic. In this controlled environment, the performance and dependability of an ADAS is tested to great accuracy and reliability. The working principle and the added value of VEHIL are demonstrated with test results of an adaptive cruise control and a forward collision warning system. On the basis of the ‘V’ diagram, the position of VEHIL in the development process of ADASs is illustrated.